Propositional logic презентация

Содержание

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Propositions Our discussion begins with an introduction to the basic

Propositions

Our discussion begins with an introduction to the basic building blocks

of logic – propositions.
Definition 1
A proposition is a declarative sentence (that is, a sentence that declares a fact) that is either true or false, but not both.
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Propositions Example 1 All the following declarative sentences are propositions.

Propositions

Example 1
All the following declarative sentences are propositions.
1. Minsk is

the capital of Belarus.
2. Toronto is the capital of Canada.
3. 1+1=2.
4. 2+2=3.
Propositions 1 and 3 are true, whereas 2 and 4 are false.
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Propositions

Propositions

 

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Propositions

Propositions

 

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Propositions The area of logic that deals with propositions is

Propositions

The area of logic that deals with propositions is called the

propositional calculus or propositional logic.
It was first developed systematically by the Greek philosopher Aristotle more than 2300 years ago.
Aristotle
(384 b.c.e.–322 b.c.e.)
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Compound propositions We now turn our attention to methods for

Compound propositions

We now turn our attention to methods for producing new

propositions from those that we already have.
These methods were discussed by the English mathematician George Boole in 1854 in his book The Laws of Thought.
George Boole
(1815–1864)
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Compound propositions Many mathematical statements are constructed by combining one

Compound propositions

Many mathematical statements are constructed by combining one or more

propositions.
New propositions, called compound propositions, are formed from existing propositions using logical operators.
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The negation of a proposition

The negation of a proposition

 

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The negation of a proposition

The negation of a proposition

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The negation of a proposition Example 3 Find the negation

The negation of a proposition

Example 3 Find the negation of the

proposition “Vandana’s smartphone has at least 32GB of memory” and express this in simple English.
Solution The negation is “It is not the case that Vandana’s smartphone has at least 32GB of memory.”
This negation can also be expressed as “Vandana’s smartphone does not have at least 32GB of memory” or even more simply as “Vandana’s smartphone has less than 32GB of memory.”
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The conjunction of two propositions Definition 3 Let p and

The conjunction of two propositions

Definition 3
Let p and q be

propositions. The conjunction of p and q, denoted by p∧q, is the proposition “p and q”. The conjunction p∧q is true when both p and q are true and is false otherwise.
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The conjunction of two propositions

The conjunction of two propositions

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The conjunction of two propositions Example 4 Find the conjunction

The conjunction of two propositions

Example 4 Find the conjunction of the

propositions p and q where p is the proposition “Rebecca’s PC has more than 16 GB free hard disk space” and q is the proposition “The processor in Rebecca’s PC runs faster than 1 GHz.”
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The conjunction of two propositions Solution The conjunction of these

The conjunction of two propositions
Solution The conjunction of these propositions, p∧q,

is the proposition “Rebecca’s PC has more than 16 GB free hard disk space, and the processor in Rebecca’s PC runs faster than 1 GHz.”
This conjunction can be expressed more simply as “Rebecca’s PC has more than 16 GB free hard disk space, and its processor runs faster than 1 GHz.”
For this conjunction to be true, both conditions given must be true. It is false, when one or both of these conditions are false.

Find the conjunction of the propositions p and q where p is the proposition “Rebecca’s PC has more than 16 GB free hard disk space” and q is the proposition “The processor in Rebecca’s PC runs faster than 1 GHz.”

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The disjunction of two propositions Definition 4 Let p and

The disjunction of two propositions

Definition 4
Let p and q be

propositions. The disjunction of p and q, denoted by p∨q, is the proposition “p or q”. The disjunction p∨q is false when both p and q are false and is true otherwise.
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The disjunction of two propositions

The disjunction of two propositions

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The disjunction of two propositions Example 5 Find the disjunction

The disjunction of two propositions

Example 5 Find the disjunction of the

propositions p and q where p is the proposition “Rebecca’s PC has more than 16 GB free hard disk space” and q is the proposition “The processor in Rebecca’s PC runs faster than 1 GHz.”
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The disjunction of two propositions Solution The disjunction of p

The disjunction of two propositions
Solution The disjunction of p and q,

p∨q, is the proposition “Rebecca’s PC has at least 16 GB free hard disk space, or the processor in Rebecca’s PC runs faster than 1 GHz.”
This proposition is true when Rebecca’s PC has at least 16 GB free hard disk space, when the PC’s processor runs faster than 1 GHz, and when both conditions are true. It is false when both of these conditions are false, that is, when Rebecca’s PC has less than 16 GB free hard disk space and the processor in her PC runs at 1 GHz or slower.

Find the disjunction of the propositions p and q where p is the proposition “Rebecca’s PC has more than 16 GB free hard disk space” and q is the proposition “The processor in Rebecca’s PC runs faster than 1 GHz.”

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The exclusive or The use of the connective or in

The exclusive or

The use of the connective or in a

disjunction corresponds to one of the two ways the word or is used in English, namely, as an inclusive or.
A disjunction is true when at least one of the two propositions is true.
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The exclusive or On the other hand, we are using

The exclusive or

On the other hand, we are using the

exclusive or when we say “Students who have taken calculus or computer science, but not both, can enroll in this class.”
Here, we mean that students who have taken both calculus and a computer science course cannot take the class. Only those who have taken exactly one of the two courses can take the class.
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The exclusive or Definition 5 Let p and q be

The exclusive or

Definition 5
Let p and q be propositions.

The exclusive or of p and q, denoted by pq, is the proposition that is true when exactly one of p and q is true and is false otherwise.
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The exclusive or

The exclusive or

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Conditional statements

Conditional statements

 

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Conditional statements

Conditional statements

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Conditional statements

Conditional statements

 

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Conditional statements

Conditional statements

 

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Conditional statements

Conditional statements

 

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Converse, contrapositive and inverse

Converse, contrapositive and inverse

 

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Converse, contrapositive and inverse

Converse, contrapositive and inverse

 

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Biconditionals

Biconditionals

 

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Biconditionals

Biconditionals

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Biconditionals

Biconditionals

 

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Biconditionals

Biconditionals

 

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Truth tables of compound propositions We have now introduced four

Truth tables of compound propositions

We have now introduced four important logical

connectives – conjunctions, disjunctions, conditional statements, and biconditional statements – as well as negations.
We can use these connectives to build up complicated compound propositions involving any number of propositional variables.
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Truth tables of compound propositions We can use truth tables

Truth tables of compound propositions

We can use truth tables to determine

the truth values of these compound propositions.
We use a separate column to find the truth value of each compound expression that occurs in the compound proposition as it is built up.
The truth values of the compound proposition for each combination of truth values of the propositional variables in it is found in the final column of the table.
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Truth tables of compound propositions Example 9 Construct the truth

Truth tables of compound propositions

Example 9 Construct the truth table of

the compound proposition (pq)  (pq).
Solution
Because this truth table involves two propositional variables p and q, there are four rows in this truth table, one for each of the pairs of truth values TT, TF, FT, and FF.
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Truth tables of compound propositions Example 9 Construct the truth

Truth tables of compound propositions

Example 9 Construct the truth table of

the compound proposition (pq)  (pq).
Solution
The first two columns are used for the truth values of p and q, respectively. In the third column we find the truth value of q, needed to find the truth value of pq, found in the fourth column.
The fifth column gives the truth value of pq.
Finally, the truth value of (pq)  (pq) is found in the last column.
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Truth tables of compound propositions Example 9 Construct the truth

Truth tables of compound propositions

Example 9 Construct the truth table of

the compound proposition (pq)  (pq).
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Truth tables of compound propositions Example 9 Construct the truth

Truth tables of compound propositions

Example 9 Construct the truth table of

the compound proposition (pq)  (pq).
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Truth tables of compound propositions Example 9 Construct the truth

Truth tables of compound propositions

Example 9 Construct the truth table of

the compound proposition (pq)  (pq).
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Truth tables of compound propositions Example 9 Construct the truth

Truth tables of compound propositions

Example 9 Construct the truth table of

the compound proposition (pq)  (pq).
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Truth tables of compound propositions Example 9 Construct the truth

Truth tables of compound propositions

Example 9 Construct the truth table of

the compound proposition (pq)  (pq).
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Precedence of logical operators

Precedence of logical operators

 

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Precedence of logical operators

Precedence of logical operators

 

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Precedence of logical operators

Precedence of logical operators

 

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Precedence of logical operators Another general rule of precedence is

Precedence of logical operators

Another general rule of precedence is that the

conjunction operator takes precedence over the disjunction operator, so that p∧q∨r means (p∧q)∨r rather than p∧(q∨r).
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Precedence of logical operators

Precedence of logical operators

 

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Tautologies and contradictions Definition 8 A compound proposition that is

Tautologies and contradictions

Definition 8
A compound proposition that is always true, no

matter what the truth values of the propositional variables that occur in it, is called a tautology.
A compound proposition that is always false is called a contradiction.
A compound proposition that is neither a tautology nor a contradiction is called a contingency.
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Tautologies and contradictions Example 10 We can construct examples of

Tautologies and contradictions

Example 10
We can construct examples of tautologies and contradictions

using just one propositional variable. Consider the truth tables of pp and pp.
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Tautologies and contradictions

Tautologies and contradictions

 

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Logical equivalences

Logical equivalences

 

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Logical equivalences One way to determine whether two compound propositions

Logical equivalences

One way to determine whether two compound propositions are equivalent

is to use a truth table.
In particular, the compound propositions p and q are equivalent if and only if the columns giving their truth values agree.
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Logical equivalences Example 11 Show that (pq) and pq are logically equivalent.

Logical equivalences

Example 11 Show that (pq) and pq are logically equivalent.


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Logical equivalences Example 11 Show that (pq) and pq are logically equivalent.

Logical equivalences

Example 11 Show that (pq) and pq are logically equivalent.


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Logical equivalences Example 11 Show that (pq) and pq are logically equivalent.

Logical equivalences

Example 11 Show that (pq) and pq are logically equivalent.


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Logical equivalences Example 11 Show that (pq) and pq are logically equivalent.

Logical equivalences

Example 11 Show that (pq) and pq are logically equivalent.


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Logical equivalences Example 11 Show that (pq) and pq are logically equivalent.

Logical equivalences

Example 11 Show that (pq) and pq are logically equivalent.


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Logical equivalences Example 2 Show that (pq) and pq are logically equivalent.

Logical equivalences

Example 2 Show that (pq) and pq are logically equivalent.


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Logical equivalences Example 11 Show that (pq) and pq are logically equivalent.

Logical equivalences

Example 11 Show that (pq) and pq are logically equivalent.


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Logical equivalences

Logical equivalences

 

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Logical equivalences (pq)  pq This logical equivalence is one

Logical equivalences
(pq)  pq
This logical equivalence is one of the

two De Morgan laws, named after the English mathematician Augustus De Morgan, of the mid-nineteenth century.
Augustus de Morgan
(1806–1871)
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Logical equivalences

Logical equivalences

 

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Logical equivalences

Logical equivalences

 

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Logical equivalences

Logical equivalences

 

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Logical equivalences

Logical equivalences

 

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Logical equivalences

Logical equivalences

 

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Logical equivalences

Logical equivalences

 

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Logical equivalences

Logical equivalences

 

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Logical equivalences We will now establish a logical equivalence of

Logical equivalences

We will now establish a logical equivalence of two compound

propositions involving three different propositional variables p, q, and r.
To use a truth table to establish such a logical equivalence, we need eight rows, one for each possible combination of truth values of these three variables. We symbolically represent these combinations by listing the truth values of p, q, and r, respectively.
These eight combinations of truth values are
TTT, TTF, TFT, TFF, FTT, FTF, FFT, and FFF;
we use this order when we display the rows of the truth table.
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Logical equivalences Example 13 Show that p∨(q∧r) and (p∨q)∧(p∨r) are

Logical equivalences

Example 13 Show that p∨(q∧r) and (p∨q)∧(p∨r) are logically equivalent.

This is the distributive law of disjunction over conjunction.
Solution: We construct truth tables for these compound propositions. Because the truth values of p∨(q∧r) and (p∨q)∧(p∨r) agree, these compound propositions are logically equivalent.
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A Demonstration That p(qr) and (pq)(pr) Are Logically Equivalent.

A Demonstration That p(qr) and (pq)(pr) Are Logically Equivalent.

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A Demonstration That p(qr) and (pq)(pr) Are Logically Equivalent.

A Demonstration That p(qr) and (pq)(pr) Are Logically Equivalent.

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A Demonstration That p(qr) and (pq)(pr) Are Logically Equivalent.

A Demonstration That p(qr) and (pq)(pr) Are Logically Equivalent.

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A Demonstration That p(qr) and (pq)(pr) Are Logically Equivalent.

A Demonstration That p(qr) and (pq)(pr) Are Logically Equivalent.

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A Demonstration That p(qr) and (pq)(pr) Are Logically Equivalent.

A Demonstration That p(qr) and (pq)(pr) Are Logically Equivalent.

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A Demonstration That p(qr) and (pq)(pr) Are Logically Equivalent.

A Demonstration That p(qr) and (pq)(pr) Are Logically Equivalent.

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A Demonstration That p(qr) and (pq)(pr) Are Logically Equivalent.

A Demonstration That p(qr) and (pq)(pr) Are Logically Equivalent.

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A Demonstration That p(qr) and (pq)(pr) Are Logically Equivalent. Because

A Demonstration That p(qr) and (pq)(pr) Are Logically Equivalent.

Because the

truth values of p∨(q∧r) and (p∨q)∧(p∨r) agree, these compound propositions are logically equivalent.
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Logical equivalences Next table contains some important equivalences. In these

Logical equivalences

Next table contains some important equivalences.
In these equivalences, T

denotes the compound proposition that is always true and F denotes the compound proposition that is always false.
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Logical equivalences

Logical equivalences

 

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Logical equivalences We also display some useful equivalences for compound

Logical equivalences

We also display some useful equivalences for compound propositions involving

conditional statements and biconditional statements in Tables 2 and 3, respectively.
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Using De Morgan’s Laws Example 13 Use De Morgan’s laws

Using De Morgan’s Laws

Example 13 Use De Morgan’s laws to express

the negations of “Miguel has a cellphone and he has a laptop computer” and “Heather will go to the concert or Steve will go to the concert.”
Solution: Let p be “Miguel has a cellphone” and q be “Miguel has a laptop computer.” Then “Miguel has a cellphone and he has a laptop computer” can be represented by p∧q. By the first of De Morgan’s laws,¬(p∧q) is equivalent to ¬p∨¬q.
Consequently, we can express the negation of our original statement as “Miguel does not have a cellphone or he does not have a laptop computer.”
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Using De Morgan’s Laws Example 13 Use De Morgan’s laws

Using De Morgan’s Laws

Example 13 Use De Morgan’s laws to express

the negations of “Miguel has a cellphone and he has a laptop computer” and “Heather will go to the concert or Steve will go to the concert.”
Solution: Let r be “Heather will go to the concert” and s be “Steve will go to the concert.” Then “Heather will go to the concert or Steve will go to the concert” can be represented by r∨s. By the second of De Morgan’s laws, ¬(r∨s) is equivalent to ¬r∧¬s.
Consequently, we can express the negation of our original statement as “Heather will not go to the concert and Steve will not go to the concert.”
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Constructing new logical equivalences The logical equivalences in Table 1,

Constructing new logical equivalences

The logical equivalences in Table 1, as well

as any others that have been established (such as those shown in Tables 2 and 3), can be used to construct additional logical equivalences.
The reason for this is that a proposition in a compound proposition can be replaced by a compound proposition that is logically equivalent to it without changing the truth value of the original compound proposition.
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Constructing new logical equivalences This technique is illustrated in Examples

Constructing new logical equivalences

This technique is illustrated in Examples 14 –

16, where we also use the fact that if p and q are logically equivalent and q and r are logically equivalent, then p and r are logically equivalent.
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Constructing new logical equivalences Example 14 Show that (p 

Constructing new logical equivalences

Example 14 Show that (p  q) and

p  q are logically equivalent.
Solution: We will establish this equivalence by developing a series of logical equivalences, using one of the equivalences in Table 1 at a time, starting with (p  q) and ending with p  q .
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Constructing new logical equivalences Example 14 Show that (p 

Constructing new logical equivalences

Example 14 Show that (p  q) and

p  q are logically equivalent.
Solution: We have the following equivalences.
(p  q)  (p  q) – by Example 12
 (p)  q – by the second De Morgan law
 p  q – by the double negation law
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Constructing new logical equivalences Example 15 Show that (p 

Constructing new logical equivalences

Example 15 Show that (p  (p 

q)) and (p  q) are logically equivalent by developing a series of logical equivalences.
Solution:
We will use one of the equivalences in Table 1 at a time, starting with (p  (p  q)) and ending with (p  q) .
(Note: we could also easily establish this equivalence using a truth table.)
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Constructing new logical equivalences Example 15 Show that (p 

Constructing new logical equivalences

Example 15 Show that (p  (p 

q)) and (p  q) are logically equivalent by developing a series of logical equivalences.
Solution: We have the following equivalences.
(p  (p  q))  p  (p  q)
 p  ((p)  q)
 p  (p  q)
 (p  p)  (p  q)
 F  (p  q)
 (p  q)  F
 (p  q)
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Constructing new logical equivalences Example 16 Show that (p 

Constructing new logical equivalences

Example 16 Show that (p  q) 

(p  q) is a tautology.
Solution:
(p  q)  (p  q)   (p  q)  (p  q)
 (p  q)  (p  q)
 (p  p)  (q  q)
 T  T
 T
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Propositional satisfiability Definition 10 A compound proposition is satisfiable if

Propositional satisfiability

Definition 10 A compound proposition is satisfiable if there is

an assignment of truth values to its variables that makes it true.
When no such assignments exists, that is, when the compound proposition is false for all assignments of truth values to its variables, the compound proposition is unsatisfiable.
Note that a compound proposition is unsatisfiable if and only if its negation is true for all assignments of truth values to the variables, that is, if and only if its negation is a tautology.
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Propositional satisfiability Definition 11 When we find a particular assignment

Propositional satisfiability

Definition 11
When we find a particular assignment of truth

values that makes a compound proposition true, we have shown that it is satisfiable;
such an assignment is called a solution of this particular satisfiability problem.
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Propositional satisfiability However, to show that a compound proposition is

Propositional satisfiability

However, to show that a compound proposition is unsatisfiable, we

need to show that every assignment of truth values to its variables makes it false.
Although we can always use a truth table to determine whether a compound proposition is satisfiable, it is often more efficient not to, as Example 17 demonstrates.
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Propositional satisfiability Example 17 Determine whether each of the compound

Propositional satisfiability

Example 17 Determine whether each of the compound propositions
(p

 q)  (q  r)  (r  p) ,
(p  q  r)  (p  q  r) ,
(p  q)  (q  r)  (r  p)  (p  q  r)  (p  q  r)
is satisfiable.
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Propositional satisfiability

Propositional satisfiability

 

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Satisfiability problem Many problems, in diverse areas such as robotics,

Satisfiability problem

Many problems, in diverse areas such as
robotics,
software testing,


computer-aided design,
machine vision,
integrated circuit design,
computer networking,
genetics,
can be modeled in terms of propositional satisfiability.
In particular, we will show how to use propositional satisfiability to model Sudoku puzzles.
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Sudoku 99 A Sudoku puzzle is represented by a 9×9

Sudoku 99

A Sudoku puzzle is represented by a 9×9 grid made

up of nine 3×3 subgrids, known as blocks.
For each puzzle, some of the 81 cells, called givens, are assigned one of the numbers 1,2,...,9, and the other cells are blank.
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Sudoku 99 The puzzle is solved by assigning a number

Sudoku 99

The puzzle is solved by assigning a number to each

blank cell so that every row, every column, and every one of the nine 3×3 blocks contains each of the nine possible numbers.
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